Downhole trigger apparatus

ABSTRACT

A selectively operable timing device is in operable communication with a force reducing mechanism. The timing device restrains an effect of an external force on a tool member through the force reducing mechanism.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to G.B. provisional application,0515070.1, filed Jul. 22, 2005, the entire contents of which areincorporated herein by reference. Further, this application is adivisional application of U.S. patent application Ser. No. 11/491,698filed Jul. 24, 2006, the entire contents of which are incorporatedherein by reference.

FIELD OF THE INVENTION

The present invention relates to an apparatus for activating a downholetool, and in particular, but not exclusively, to a downhole tooltriggering apparatus.

BACKGROUND OF THE INVENTION

Many downhole well bore tools require to be activated when locateddownhole at the required location or depth. There are many systemsavailable, which may be utilized to perform such actuation, and mayinclude downhole motors, piston arrangements or the like. However, it issometimes the case that such systems require to be powered or carefullymonitored and controlled from surface level to ensure reliable andcorrect operation. This therefore required relatively complexarrangements of conduits and power cables and the like to be run fromsurface level to the required depth.

Simplified arrangements, therefore, of downhole tool actuation aredesirable in the art.

BRIEF DESCRIPTION OF THE INVENTION

Disclosed herein is a selectively operable timing device in operablecommunication with a force reducing mechanism. The timing devicerestrains an effect of an external force on a tool member through theforce reducing mechanism.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other aspects of the present invention will now be described,by way of example only, with reference to the accompanying drawings, inwhich:

FIG. 1 is a perspective view of a bridge plug tool shown in a retractedconfiguration;

FIG. 2 is a perspective view of the tool of FIG. 1, shown in an extendedconfiguration;

FIGS. 3A to 3D present a longitudinal sectional view of the tool of FIG.1;

FIGS. 4 to 7 are enlarged part sectional views of a ratchet arrangementof the tool of FIG. 1;

FIGS. 8 and 9 are perspective views of the tool of FIG. 1, showing thetool being moved to a retracted configuration;

FIG. 10 is a longitudinal sectional view of a setting tool suitable foruse in activating the bridge plug tool of FIG. 1, wherein the settingtool is shown in an unstroked, first configuration;

FIG. 11 is a longitudinal sectional view of the tool of FIG. 10, shownin a stroked (setting), second configuration;

FIGS. 12 and 13 are enlarged part sectional views of a portion of thetool shown in broken outline in FIGS. 10 and 11;

FIG. 14 is a longitudinal sectional view of a trigger tool in accordancewith an embodiment of an aspect of the present invention, which may beused in conjunction with the setting tool of FIGS. 10 and 11, whereinthe trigger tool is shown in a locked, first configuration;

FIG. 15 is a longitudinal sectional view of the trigger tool of FIG. 14,shown in an unlocked (triggered), second configuration; and

FIGS. 16 and 17 are enlarged part sectional perspective views of thetool of FIGS. 14 and 15, shown in the first and second configurationsrespectively.

DETAILED DESCRIPTION OF THE INVENTION

Reference is first made to FIGS. 1 and 2 of the drawings, which showperspective views of a downhole bridge plug tool, generally identifiedby reference numeral 10. The tool 10 is shown located in a portion of acased well bore 12, and in FIG. 1 is shown in a retracted, firstconfiguration, and in FIG. 2 is shown in an expanded, secondconfiguration.

The tool 10 comprises an outer tool body 14 mounted on a tool mandrel16, and a number of extendable assemblies 18 mounted on an outer surfaceof the tool 10. As shown, the extendable assemblies 18 are arranged intwo axially spaced sets, 20, 22, wherein each set 20, 22 comprises threeextendable assemblies 18 circumferentially distributed about the outersurface of the tool 10. The extendable assemblies 18 of the first set 20are pivotally mounted between a first support portion 24 and a secondsupport portion 26, and the extendable assemblies 18 of the second set22 are pivotally mounted between the second support portion 26 and athird support portion 28. The first support portion 24 is fixed relativeto the tool mandrel 16 and the second and third support portions 26, 28are axially slidably mounted relative to the tool mandrel 16.

The tool 10 further comprises an outer sleeve assembly 30 slidablymounted relative to the tool mandrel 16, wherein a lower end 30 a of theouter sleeve assembly 30 engages the third support portion 28. In use,the sleeve assembly 30 is caused to move downwardly relative to the toolmandrel 16 towards the leading end nose 94 to transmit a force to thethird support portion 28, thus causing the second and third supportportions 26, 28 to be displaced downwardly relative to the tool mandrel16 to cause the extendable assemblies 18 to extend radially outwardly,as shown in FIG. 2, into engagement with the wall 32 of the bore 12. Inthis configuration, the tool is advantageously secured within the bore12 by the interference engagement created between the extendableassemblies 18 and bore wall. The outer sleeve assembly 30 may be causedto move downwardly relative to the tool mandrel 16 by an appropriatesetting tool (not shown in FIGS. 1 and 2), such as that shown in FIGS.10 to 13.

The outer sleeve assembly 30 incorporates a sealing member 34 which isadapted to be moved between a retracted configuration, as shown in FIG.1, and an extended or sealing configuration, as shown in FIG. 2. Thearrangement is such that when the extendable assemblies 18 are engagedwith the bore wall 32 to provide support, continued downward movement ofthe outer sleeve assembly 30 will cause the sealing member to bedeformed radially outwardly and ultimately brought into sealingengagement with the bore wall 32. Thus, the established seal may beutilized to prevent or at least minimize the transmission of fluidsbetween upper and lower regions 36, 38 of the well bore 12.

A more detailed description of the tool 10 will now be given withreference to FIG. 3 in which there is shown a longitudinal sectionalview of the tool 10, in the configuration of FIG. 1. For clarity, thetool 10 in FIG. 3 is presented on 4 separate sheets, in FIGS. 3A-3D.

An upper portion of the tool 10 is shown in FIG. 3A, in which there isshown a portion 16 a of the outer sleeve assembly 30 mounted on the toolmandrel 16. An end portion of the mandrel 16 incorporates a threadedportion 40 for securing to a further tool, such as a setting tool,either directly or via a suitable connector. The outer sleeve assembly30 comprises an outer sleeve load transfer sub 42 having an annular endface 44 against which a loading tool, such as a setting tool, may abutto transmit an axial force to the load transfer sub 42, which force isultimately transmitted to the third support portion 28 (FIGS. 1 and 2)and seal portion 34 (FIGS. 1 and 2) to reconfigure the tool 10.Accordingly, when the tool 10 is reconfigured, the outer sleeve assembly30 is moved downwardly, in the direction of arrow 46, relative to thetool mandrel 16.

The outer sleeve assembly 30 further comprises a ratchet arrangement,generally indicated by reference numeral 48, adapted to freely permitmovement of the sleeve assembly 30 in the direction of arrow 46 relativeto the tool mandrel 16, and to selectively permit relative movement ofthe outer sleeve assembly 30 and tool mandrel 16 in a direction oppositeto arrow 46. Thus, the ratchet arrangement 48 is adapted to temporarilylock the tool 10 in the extended configuration (shown in FIG. 2). Adetailed description of the ratchet arrangement 48 and its operation isprovided hereinafter below.

Reference is now made to FIG. 3B in which the remaining portion of theouter sleeve assembly 30 is shown. As noted above, the assembly 30comprises sealing member 34, which is secured with the sleeve assembly30 by threaded connections 50, 52, and is supported by seal supports 54,56. The sealing member defines upper and lower annular notches 58, 60 inan outer surface thereof, and a central annular notch 62 in an innersurface thereof, such that when a predetermined axial load is impartedon the outer sleeve assembly 30, the sealing member 34 deforms at thelocation of the notches 58, 60, 62 to provide the required sealextension. The sealing member may be of a form such as that described inapplicant's co-pending international patent application, publicationnumber WO 02/04783.

The third support portion 28 is secured to the lower end of the sealingmember 34 via a threaded connector sleeve 64. When the tool 10 isinitially set in the retracted position, the third support portion 28 issecured to the tool mandrel 16 via one or more shear screws 66 which areadapted to be sheared when the outer sleeve assembly 30 is subjected toa predetermined axial load. Once the shear screws 66 have been sheared,the third support portion 28 may then be displaced axially relative tothe tool body 16 by the outer sleeve assembly 30, thus causing theextendable assemblies 18 to be extended radially outwardly. Thisarrangement assists to prevent unintentional extension of the extendableassemblies 18, for example when running into a well bore.

In the embodiment shown, the axial force required to shear the shearscrews 66 is less than that required to deform the sealing member 34.Accordingly, any axial load applied to the outer sleeve assembly 30 willadvantageously be transmitted by the sealing member 30 and applied tothe third support portion 28 via the connector sleeve 64 in order toshear the shear screws 66, and subsequently effect extension of theextendable assemblies 18, without any deformation of the sealing member34 occurring. Once the extendable assemblies 18 engage the wall of abore, an increased reaction force will be achieved such that anincreased force may be applied by the outer sleeve assembly 30 to effectdeformation and activation of the sealing member 34. Thus, the tool 10is adapted to be located at the required bore depth, fixed in locationby the extendable assembly 18, and then establish a seal via the sealingmember 34.

A collar 68 is mounted about the outer surface of the tool mandrel 16,beneath the sealing member 34. In use, when the sealing member 34 isbeing deformed, the seal supports 54, 56 will engage either side of thecollar 68, thus limiting the amount of deformation of the sealing member34 which may be achieved. The collar 68 may be fixed to the tool mandrel16, or may be slidably mounted on the mandrel 16.

The form of the extendable assemblies 18 will now be described withreference to FIG. 3C, in which a longitudinal sectional view of acomplete extendable assembly 18 of the second set 22 (FIGS. 1 and 2) isshown, which extends between the third support portion 28 and secondsupport portion 26. As noted above, the second support portion 26 isslidably mounted relative to the tool mandrel 16 such that relativedownward movement of the second support portion 26 will be achieved whenthe third support portion 28 is caused to move axially by the outersleeve assembly 30. The second support portion 26 will be caused to moveat a slower rate of displacement than the third support portion 28 inorder to establish relative movement therebetween. Also shown in FIG. 3Cis a portion of an extendable assembly 18 of the first set 20 (FIGS. 1and 2), which extends between the second support portion 26 and thefirst support portion 24 (FIG. 3D). As previously noted, the firstsupport portion 24 is fixed relative to the tool mandrel 16.Accordingly, when the outer sleeve assembly 30 applies an axial force,relative downward movement of the second and third support portions 26,28 with respect to the tool mandrel 16 will result in extension of theextendable assemblies 18.

Each extendable assembly 18 comprises a central engaging member 70supported between first and second connecting members 72, 74. The outersurface 71 of the engaging member 70 is adapted to engage the wallsurface of the bore within which the tool 10 is located. In theembodiment shown, the outer surface 71 of the engaging member comprisesserrations 73 to aid the grip between the member 70 and bore wall.Alternatively, tungsten carbide inserts or the like may be utilized.

As shown in the complete example in FIG. 3C, one end of the firstconnecting member 72 is pivotally coupled to the third support portion28 about pivot axis 76, and an opposite end of the first connectingmember 72 is pivotally coupled to the engaging member 70 about pivotaxis 78. Similarly, one end of the second connecting member 74 ispivotally coupled to the engaging member 70 about pivot axis 80, and anopposite end of the second connecting member 74 is pivotally coupled tothe second support portion 26 about pivot axis 82. The pivot axes 76,78, 80, 82 are aligned parallel with each other, and are obliquelyaligned and radially offset from the central longitudinal axis 84 of thetool 10.

In the preferred arrangement shown in the Figures, pivot axes 76, 78 arelaterally offset from each other relative to the central axis 86 of thefirst connecting member 72. That is, pivot axis 76 is positioned closerto an inner surface 90 of the first connecting member 72 than pivot axis78. In a similar fashion, pivot axis 82 is positioned closer to theinner surface 92 of the second connection member 74 than axis 80. Thisspecific arrangement of the respective pairs of pivot axes 76, 78 and80, 82 advantageously results in the transmission of an axial force,applied by the outer sleeve assembly 30, between the offset pivot axespairs at an oblique angle relative to the longitudinal axis 84 of thetool 10, such that the engaging member 70 will consistently be movedradially outwardly. Arranging the pivot axes in the particular mannershown and described beneficially eliminates or at least minimizes thepossibility of the engaging members 70 being forced in a radially inwarddirection which would cause the extendable assemblies 18 to becomejammed, which may cause premature extension of the sealing member 34.

The lower end of the tool 10 is shown in FIG. 3D. A conical nose portion94 is secured to the lower end of the tool mandrel 16 via a threadedconnection 96. The first support portion 24 is secured to the noseportion 94 via a threaded connector sleeve 98, such that the firstsupport 24 portion is at least axially fixed relative to the toolmandrel 16.

The form and function of the ratchet arrangement 48, initially shown inFIG. 3A, will now be described in detail with reference to FIGS. 4 to 7.

Reference is initially made to FIG. 4 in which there is shown a partsectional view of the tool 10 in the region of the ratchet arrangement48. The outer sleeve assembly 30 comprises an outer sleeve or loadtransfer sub 42, which as noted above is adapted to transfer a loadapplied from an external tool. The sub 42 is secured to an inner sleeve100 via a grub screw 102, and the inner sleeve 100 is also initiallysecured to an outer release sleeve 104 via a plurality of shear screws106. The outer release sleeve 104 is secured to the upper end of thesealing member 34 by the threaded connection 50. Additionally, the outerrelease sleeve 104 is also secured to a ratchet mandrel 108 via athreaded connection 110. Thus, the arrangement is such that duringnormal use of the tool a permanent connection is provided between thesub 42 and inner sleeve 100, and a permanent connection is providedbetween the outer release sleeve 104, sealing member 34 and ratchetmandrel 108, while the inner sleeve 100 and outer release sleeve 104 aretemporarily secured together by virtue of the shear screws 106.

The ratchet mandrel 108 defines two diametrically opposed apertures 112(only one shown) within which is located a ratchet component 114, spacerelement 116 and a ratchet reverser component 118. The ratchet component114 defines a ratchet profile on an inner surface thereof, which isadapted to engage and cooperate with a ratchet profile 120 on the outersurface of the tool mandrel 16. The ratchet component 114 is removed inFIG. 5 to clearly show the ratchet profile 120 of the tool mandrel 16.Referring again to FIG. 4, when in use, the ratchet arrangement 48 willpermit movement of the outer sleeve assembly 30 in the direction ofarrow 46. That is, the ratchet profiles on the ratchet component 114 andtool mandrel 16 will cooperate to ratchet the ratchet component 114radially outwardly into an annular cavity 122 defined between the innersleeve 100 and the ratchet mandrel 108. However, when relative movementof the tool mandrel 16 and outer sleeve assembly 30 is attempted in theopposite direction to that indicated by arrow 46, cooperation of theratchet profiles on the tool mandrel 16 and ratchet component 114 willcause the outer sleeve assembly 30 and tool mandrel 16 to become axiallylocked together.

When it is required to reconfigure the tool 10 from the extendedconfiguration to the retracted configuration, it is necessary todisengage the ratchet profiles of the ratchet component 114 and toolmandrel 16. To achieve this, a tool (not shown) is coupled to the innersleeve 100 via fishneck 123, wherein the tool pulls on the inner sleeve100 in the direction of arrow 124 shown in FIG. 6, reference to which isnow made. The tool used to pull on the inner sleeve 100 may be the samesetting tool used to position the extendable assemblies 18 and sealingmember 34 into extended configurations. Alternatively, a different toolmay be used. When a predetermined axial force is achieved by the toolpulling on the inner sleeve 100, the shear screws 106 will shear, thussevering the connection between the inner sleeve 100 and the outerrelease sleeve 104, permitting the inner sleeve 100 and load transfersub 42 to be displaced upwardly in the direction of arrow 124. Upwarddisplacement of the inner sleeve 100 will be permitted until an annularface 126 of the inner sleeve 100 engages an annular face 128 of theouter release sleeve 104. In this position, the ratchet reversercomponent 118 is no longer enveloped by the inner sleeve 100.

Reference is now made to FIG. 7 of the drawings in which there is shownan enlarged view of the ratchet arrangement 48, shown in a releasedposition. When the inner sleeve 100 has been displaced to uncover theratchet reverser component 118, an axial force may be applied to thetool mandrel 16 to move the mandrel in the direction of arrow 130relative to the outer sleeve assembly 30. Movement of the tool mandrel16 in this direction will translate the ratchet component 114 in thesame direction by virtue of the engaging ratchet profiles 120 such thatthe spacer element 116 is forced under the ratchet reverser component118 to displace the component 118 radially outwardly into the annularspace 132 previously occupied by the inner sleeve 100. Furthermore,movement of the ratchet component 114 in the direction of arrow 130 willcause the ratchet component 114 to be displaced radially outwardly ofthe aperture 112 by cooperation of engaging ramp profiles 134 on theratchet component 114 and ratchet mandrel 108, thus disengaging theratchet profiles to permit the tool mandrel 16 to then be freelydisplaced in the direction of arrow 130 relative to the outer sleeveassembly 30 in order to move the extendable assemblies 18 and sealingmember 34 towards a retracted configuration, as discussed below withreference to FIGS. 8 and 9.

Referring initially to FIG. 8, which is a part sectional side view ofthe tool 10, when the ratchet arrangement 48 is released, downwardmovement of the tool mandrel 16 in the direction of arrow 130 relativeto the outer sleeve assembly 30 will initially cause the extendableassemblies 18 to be moved to a retracted position. Once the assemblies18 are fully retracted, further displacement of the tool mandrel 16 willcause the sealing member 34 to be retracted, as shown in the perspectiveview in FIG. 9. Once in this configuration, the tool may be retrieved tosurface, where it may be reset, for example by replacing shear screws 66(FIG. 3B) and 106 (FIG. 4).

As noted above, a setting tool may be utilized to move the tool 10towards an extended configuration in which the extendable assemblies 18and sealing member 34 are brought into engagement with a bore wall. Apreferred setting tool, which is suitable for use with the tool 10, willnow be described, with reference to FIGS. 10 to 13.

Reference is first made to FIG. 10 in which there is shown alongitudinal sectional view of a setting tool, generally identified byreference numeral 150, shown located within a cased bore, which forconvenience is identified by reference numeral 12. The setting tool 150comprises an inner member 152 and an outer member 154 slidably mountedon the inner member 152. The inner member 152 is formed by threadablycoupling together a plurality of inner modular sections 156 end to end,and similarly, the outer member 154 is formed by threadably couplingtogether a plurality of outer modular sections 158. The lowermost innermodular section 156 a is adapted to be secured to the upper end of thetool mandrel 16 of the bridge plug tool 10 described above.Additionally, the lowermost outer modular section 158 a is adapted to besecured to the outer sleeve assembly 30 of the bridge plug tool 10,either directly or preferably via an intermediate connecting sleeve (notshown).

The uppermost inner section 156 b is adapted to be secured to a furtherdownhole tool (not shown), such as a trigger tool used to actuate thesetting tool 150, via a connector 160 which is threadably coupled at oneend to the inner module 156 b, and comprises a nipple portion 162 at theother end for engagement with the further downhole tool. A preferredexample of a trigger tool for use in actuating the setting tool 150 ofthe present invention is described hereinafter with reference to FIGS.14 to 17.

The inner member 152 defines a central bore 164 extending from an endface of the uppermost inner module 156 b and terminating in the regionof the lowermost inner module 156 a. The central bore 164 is inselective fluid communication with fluid contained with well bore 12 viafluid port 166 in the nipple portion 162 of the connector 160. Selectivefluid communication is achieved by the insertion and removal of a pistonmember (not shown) into and from the fluid port 166, wherein the pistonmember forms part of a further downhole tool, an example of which isshown in FIGS. 14 to 17, which is described below.

The inner member 152 further defines a plurality of transverse bores 168axially distributed along the length of the inner member 152, whereinthe bores 168 communicate with the central bore 164. Each transversebore 168 is aligned with a respective bore 170 formed in the outermember 154, wherein the bores 170 are in fluid communication withrespective piston chambers 172 defined between the inner and outermembers 152, 154.

In use, the port 166 is opened which will permit well bore fluid toenter the central bore 164, and into the piston chambers 172 viarespective aligned bores 168, 170. The hydrostatic pressure of the wellbore fluid will cause the piston chambers 172 to fill with well borefluid, thus forcing the outer member 154 to move relative to the innermember 152 in the direction of arrow 174, as shown in FIG. 11. Thus,this movement of the outer member 154 may be transmitted to the outersleeve assembly 30 of the bridge plug tool 10 to reconfigure the bridgeplug tool 10. An enlarged view of a piston chamber 172 is shown in FIG.12 with the outer member 154 in a retracted position, and in FIG. 13with the outer member 154 in an extended position with the pistonchamber 172 filled with well bore fluid communicated from the well borevia bores 164, 168 and 170.

While the setting tool 150 has been described above for use inactivating the bridge plug tool 10 of FIGS. 1 to 9, it should beunderstood that the setting tool 150 may be utilized with any otherdownhole tool that requires some form of mechanical actuation.

As noted above, the setting tool 150 may be actuated by a trigger toolwhich permits selective fluid communication between the well bore 12 andthe central bore 164 in order to fill the piston chambers 172 with wellbore fluid. A trigger tool in accordance with an embodiment of an aspectof the present invention, which is suitable for use in actuating tool150 will now be described, with reference to FIGS. 14 to 17.

Referring initially to FIG. 14, there is shown a longitudinal sectionalview of a trigger tool, generally identified by reference numeral 180,which may be utilized in conjunction with the setting tool 150 describedabove. The trigger tool 180 comprises an upper connector 182 forcoupling the tool 180 to the lower end of a support (not shown), such asa tubing string, coiled tubing, wireline or the like. The upperconnector 182 is coupled to a first tool body 184 via a threadedconnection 186, and the first tool body 184 is secured to a lower,second tool body 188 via threaded connection 190. Mounted on the lowerend of the second tool body 188 is a lower connector 192 adapted to becoupled to the connector 160 of the setting tool 150 via nipple 162which is received in bore 194 in the lower connector 192, and securedtherein via grub screw 196. It should be noted that in the embodimentshown, no fluid sealing is provided between the connector 160 of thesetting tool 150 and the connector 192 of the trigger tool 180, thuspermitting the bore 194 to be exposed to well bore pressure.

Slidably mounted within the lower end of the second tool body 188 is adifferential plug 198 comprising a piston portion 200, wherein thepiston portion 200 is adapted to be received within the port 166 in theconnector 160 of the setting tool 150 in order to prevent fluidcommunication between the well bore 12 and central bore of tool 150.Fluid sealing is achieved between the piston portion 200 and port 166via a pair of O-ring seals 202 mounted on the piston portion 200,whereas fluid sealing is achieved between the piston portion 200 and thesecond tool body 188 via a pair of O-ring seals 206, also mounted on thepiston portion 200. To actuate the setting tool 150, the differentialplug 198 is permitted to move in the direction of arrow 204 under theaction of the hydrostatic pressure of the well bore fluid acting acrossthe differential piston between the O-ring seals 202, 206, as describedbelow.

Between the O-ring seals 202, 206, the differential plug 198 defines twodissimilar piston areas that may be exposed to hydrostatic well borepressure. That is, O-ring seals 202 are mounted on a first section 208of the piston plug 200, which defines a first diameter, whereas O-ringseals 206 are mounted on a second section 210, which defines a second,larger diameter. Accordingly, the difference in piston area in thepresence of well bore pressure exerts a force on the piston plug 200which will bias the plug in the direction of arrow 204. In order toensure communication of well bore pressure with the first and secondsections 208, 210 of the piston plug 200, a plurality of slots 212 areprovided around the outer surface of the connector 192, wherein theslots 212 are aligned with an annular notch 214 and a number of bores216 formed in the second tool body 188, such that well bore fluid willbe communicated to annular chamber 218.

The trigger tool 180 comprises a releasable locking arrangement adaptedto maintain the differential plug 198 in the position shown in FIG. 14,in order to maintain the piston portion 200 sealed within the port 166of the setting tool 150. When required, the locking arrangement isreleased thus permitting movement of the plug 198 by well bore pressureto open port 166 in tool 150.

The locking arrangement comprises a primary lever 220, which is shown ina locked position in FIG. 14, wherein a face 222 of the primary lever220 engages and restrains the plug 198 from stroking. The primary lever220 engages a first rolling lever 224 of a linear gear train 226,wherein the linear gear train 226 is locked by a locking lever 228 inwhich the locking lever 228 engages and is secured between the finalrolling lever 230 of the linear gear train 226 and a locking trip nut232. The locking trip nut 232 is threadably mounted on a lead screw 234,which is adapted to be driven by a wind-up clock mechanism 236 via atorque coupling 238. To unlock the locking arrangement, the lead screw234 is rotated to move the locking trip nut 232 in the direction ofarrow 204, such that the locking lever 228 is free to pivot in aclockwise direction about pivot axis 240, as shown in FIG. 15. Thus,when the locking lever 228 is disengaged from the locking trip nut 232,the pressure force acting on the differential plug 198 will cause theplug to move in the direction of arrow 204 causing the primary lever 220to pivot in an anti-clockwise direction about pivot axis 242. Theprimary lever 220 will apply a force on the first rolling lever 224 ofthe linear gear train, 226, which will be transmitted through to thefinal rolling lever 230 and ultimately to the locking lever 228 whichwill be caused to pivot in a clockwise direction. The linear gear train226 advantageously reduces the force applied on the locking lever 228and locking trip nut 232 by the external fluid pressure force acting onthe plug 198. Otherwise, the force applied would be too great to beovercome by the torque of the wind-up mechanism 236, thus preventing therelease of the primary lever 220 to permit movement of the plug 198.

Although the embodiments disclosed use the well bore fluid pressure tocreate the external force on the differential plug 198 it should beunderstood that the external force could be provided by an alternatebiasing member, such as a spring, for example.

An enlarged part sectional perspective view of the locking arrangementis shown in FIG. 16, in which the arrangement is shown in a lockedconfiguration, and in FIG. 17 in which the arrangement is shown in anunlocked configuration. The locking trip nut 232 comprises a pair ofarms 244, which extend into respective elongate guide slots 246 (onlyone shown) which prevent rotation of the nut 232 as the lead screw 234is rotated. Additionally, the locking lever 228 comprises a pair ofparallel arm 248 which permit engagement with an underside of thelocking trip nut 232, while preventing interference with the lead screw234 when the locking lever 228 is permitted to pivot clockwise aboutpivot axis 240.

While the trigger tool 180 has been described above for use with thesetting tool 150 shown in FIGS. 10 to 13, it should be understood thatthe tool 180 may be used with any other suitable downhole tool thatrequires a form of mechanical actuation.

It should be understood that the embodiments described above are merelyexemplary and that various variations may be made without departing fromthe scope of the invention. For example, any number of extendableassemblies 18 may be provided with the bridge plug tool 10, andadditionally any number of sealing members 34 may be incorporated.

Additionally, the setting tool 150 may comprise any number of pistonchambers 172. Further, the connector 160 may be integrally formed withinner member 152. Furthermore, the tool 150 may be adapted to be coupledto any other suitable tool or tools, and is not limited for use with thebridge plug tool 10 and trigger tool 180 described above. In thisregard, any suitable form of connector 160 may be utilized.Additionally, the tool 150 is adapted to be actuated by the hydrostaticpressure of the well bore fluid. However, the tool 150 may be suppliedwith fluid under pressure from surface level via a suitable conduit.

The trigger tool 180 may incorporate a suitable mechanical drive means,such as an electric motor, or an electronic timer in place of thewind-up clock mechanism 236. Additionally, the wind up clock could be a12-hour clock such as an Amerada™ 12-hour clock for example.Additionally, the trigger tool 180 may be activated in response to achange in an environmental condition such as pressure, for example.Additionally, the trigger tool 180 may be activated from a remotelocation, such as the surface, for example. Additionally, any suitableconnector may be utilized in place of the connector 192, depending onthe form of tool with which the trigger tool 180 is intended to be used.

While the invention has been described with reference to an exemplaryembodiment or embodiments, it will be understood by those skilled in theart that various changes may be made and equivalents may be substitutedfor elements thereof without departing from the scope of the invention.In addition, many modifications may be made to adapt a particularsituation or material to the teachings of the invention withoutdeparting from the essential scope thereof. Therefore, it is intendedthat the invention not be limited to the particular embodiment disclosedas the best mode contemplated for carrying out this invention, but thatthe invention will include all embodiments falling within the scope ofthe claims.

1. A selectively operable timing device in operable communication with aforce reducing mechanism, the timing device restraining an effect of anexternal force on a tool member through the force reducing mechanism. 2.The selectively operable timing device in operable communication with aforce reducing mechanism of claim 1, wherein the effect is movement. 3.The selectively operable timing device in operable communication with aforce reducing mechanism of claim 1, wherein the tool member is apiston.
 4. The selectively operable timing device in operablecommunication with a force reducing mechanism of claim 1, wherein theexternal force is due to pressure acting on the tool member.
 5. Theselectively operable timing device in operable communication with aforce reducing mechanism of claim 1, wherein the external force issupplied by a biasing member.
 6. The selectively operable timing devicein operable communication with a force reducing mechanism of claim 5,wherein the biasing member is a spring.
 7. The selectively operabletiming device in operable communication with a force reducing mechanismof claim 1, wherein the force reducing mechanism includes a series oflevers.
 8. The selectively operable timing device in operablecommunication with a force reducing mechanism of claim 7, wherein theseries of levers is in a form of a rolling lever.
 9. The selectivelyoperable timing device in operable communication with a force reducingmechanism of claim 1, wherein the selectively operable timing device isa clock.
 10. The selectively operable timing device in operablecommunication with a force reducing mechanism of claim 9, wherein theclock is a wind up clock.
 11. The selectively operable timing device inoperable communication with a force reducing mechanism of claim 1,wherein the selectively operable timing device is activated in responseto a change in environment.
 12. The selectively operable timing devicein operable communication with a force reducing mechanism of claim 11,wherein the change in environment is a change in pressure.
 13. Theselectively operable timing device in operable communication with aforce reducing mechanism of claim 1, wherein a torque coupling deviceoperably connects the selectively operable timing device to the forcereducing mechanism.
 14. The selectively operable timing device inoperable communication with a force reducing mechanism of claim 1,wherein the selectively operable timing device is an electronic timer.